Litcius/Paper detail

Electron Acceleration during Macroscale Magnetic Reconnection

Harry Arnold, J. F. Drake, M. Swisdak, Fan Guo, Joel Dahlin, Bin Chen, Gregory D. Fleishman, Lindsay Glesener, Eduard P. Kontar, T. D. Phan, Chengcai Shen

2021Physical Review Letters144 citationsDOIOpen Access PDF

Abstract

The first self-consistent simulations of electron acceleration during magnetic reconnection in a macroscale system are presented. Consistent with solar flare observations, the spectra of energetic electrons take the form of power laws that extend more than two decades in energy. The drive mechanism for these nonthermal electrons is Fermi reflection in growing and merging magnetic flux ropes. A strong guide field suppresses the production of nonthermal electrons by weakening the Fermi drive mechanism. For a weak guide field the total energy content of nonthermal electrons dominates that of the hot thermal electrons even though their number density remains small. Our results are benchmarked with the hard x-ray, radio, and extreme ultraviolet observations of the X8.2-class solar flare on September 10, 2017.

Topics & Concepts

Magnetic reconnectionPhysicsAccelerationElectronCondensed matter physicsPlasmaClassical mechanicsNuclear physicsSolar and Space Plasma DynamicsNuclear Physics and ApplicationsMagnetic confinement fusion research